Note : Les descriptions sont présentées dans la langue officielle dans laquelle elles ont été soumises.
CA 02394415 2002-07-22
DESCRIPTION
GENERATOR FOR PRODUCING HIGH VOLTAGES
TECHNICAL FIELD
The present invention relates to the field of
electricity generation. It relates in particular to a
generator for producing high voltages as claimed in the
precharacterizing clause of claim 1. In this case, high
voltages are regarded as those voltages which are above
the normal 10 to 25 kV.
PRIOR ART
One such generator is known, for example, from the
document WO-A2-97/45919.
Generators having indirect liquid cooling on the stator
side are known from the prior art, in which oil is used
as the heat-carrying medium and as an insulating
medium. Solutions such as these are described, by way
of example, in the documents CH-A5-663120, DE-C2-29 15
390, and DE-A1-33 37 632.
Furthermore, cable-insulated generators are known, in
which the stator conductor in the end winding is air-
cooled, but the heat losses from the stator core are
dissipated via a separate water circuit. In the case of
generators with cables with grounded insulation in the
generator winding, the field in the insulation is in
this case controlled by a grounded semiconductive layer
on the outer surface of the cable, (see, for example,
the article by M. Leijon, Powerformer - a radically new
rotating machine, ABB Review 2 (1998)).
These known cable-insulated generators are subject to
the problem that the heat losses in the stator core and
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in the end windings are dissipated by different heat-
carrying media. A further difficulty is uniform
grounding of the field-controlling semiconductive layer
on the cable winding, in order to ensure optimum field
control.
DESCRIPTION OF THE INVENTION
The object of the invention is thus to provide a cable-
insulated generator which avoids the disadvantages of
the known solutions and, in particular, allows
continuous uniform cooling of the stator, and optimum
field control for the cables in the stator winding.
The object is achieved by the totality of the features
in claim 1. The essence of the invention is to
accommodate the entire stator, with the laminated core
and the stator winding (including the end windings), in
a housing which is closed in a liquid-tight manner. and
has a cutout for the rotor, with the interior of the
housing being filled with a cooling liquid. The cooling
liquid carries out a number of main functions: the heat
losses produced in the laminated core are dissipated
via the surface of the laminated core (and possibly
appropriately designed openings in the laminated core)
through the circulating cooling liquid. The heat losses
in the end winding are likewise dissipated via the
cooling liquid. Both the insulated conductors and the
stator core have a single cooling medium flowing around
them, at a temperature which is as low as possible;
there are no further thermal junctions having a power
limiting effect. The thermal storage capacity of the
cooling liquid can have an advantageous effect on the
short-term load rating of the generator; this is
increased.
Water is preferably used as the cooling liquid, with
means being provided to prevent corrosion of the
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laminated core of the stator. The corrosion-inhibiting
means comprise, in particular, impregnation of the
- laminated core. However, a corrosion-inhibiting
inhibitor can also be added to the water in the
housing.
The cables of the stator winding preferably have solid
insulation, and the cooling liquid has a predetermined
electrical conductivity, in order to control the
20 electric field and the field distribution in the
insulation. There is therefore no longer any need for
the cable insulation field to be controlled via a
grounded semiconductor layer which is applied to the
cable, and this can be done via the appropriately
regulated electrical conductivity of the cooling
liquid. The field distribution in the insulation thus
becomes very homogeneous, since the potential on the
cable surface is uniformly grounded (in the end
winding, potential differences are effectively
dissipated between the cable surfaces of crossing
cables).
Special consideration must be given to any influence
from the water on the insulation characteristics of the
conductor cable. This can advantageously be achieved by
impregnation of the surface semiconductor layer, and/or
by the surface of the cable insulation of the stator
winding being provided with a protective layer. This
may be done, for example, by means of a silicone
coating.
In principle, the cooling liquid (the water) will
circulate automatically due to the non-uniform heat
distribution in the housing. However, a circulation
pump may also be provided in the housing, in order to
increase the circulation of the cooling liquid.
The heat dissipation from the stator is further
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improved by providing additional openings, through
which the cooling liquid flows, in the laminated core
of the stator.
Heat is expediently extracted from the cooling liquid
via a cooler.
Cable connections are preferably arranged outside the
liquid area. For this purpose, the cables are passed
out of the housing via sealing elements, which are
known per se.
BRIEF DESCRIPTION OF THE FIGURES
The invention will be explained in more detail in the
following text with reference to exemplary embodiments
and in conjunction with the drawing. The single figure
shows a simplified schematic illustration, in the form
of a longitudinal section, of a generator according to
one preferred exemplary embodiment of the invention.
APPROACHES TO IMPLEMENTATION OF THE INVENTION
The figure shows a simplified schematic illustration,
in the form of a longitudinal section, of a generator
10 for producing high voltages, according to one
preferred exemplary embodiment of the invention. The
generator 10 has a (central) rotor 12, which is mounted
such that it can rotate about a rotation axis 18 and is
surrounded (coaxially) on the outside by a stator 11.
The stator 11 essentially comprises a laminated core
28, with corresponding axial slots, in which a stator
winding 15 is accommodated, which is formed from an
insulated high-voltage cable. On each of the two end
faces outside the laminated core 28, the stator winding
15 forms an end winding 16. Generator outgoers 17 are
provided for outputting the high voltage which is
induced in the stator winding 15.
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The stator 11, together with the laminated core 28 and
the stator winding 15 including the end windings 16, is
arranged in a housing 13 which is sealed in a liquid-
s tight manner, and whose interior 14 is filled with
treated water as the cooling liquid. Cooling liquids
other than water may be used just as well. The housing
14 accommodates the rotor 12 and is likewise sealed
with respect to the rotor, so that the rotor 12 can be
operated with its own gas cooling. Such gas cooling may
- as indicated by arrows in the figure - either
comprise a closed cooling circuit 25, which is kept in
motion by a blade system 27 on the rotor 12 and
dissipates the heat from the cooling medium by means of
coolers 26 which are connected in the circuit (lower
half of the rotor 12 in the figure). However, an open
cooling circuit 23 (open ventilation) may also be
provided, in which the cooling medium, which flows in
from the outside, is fed through appropriate filter
mats 24 (upper half of the rotor 12 in the figure).
The cooling liquid, water, which circulates in the
interior 14 is preferably moved in the direction of the
flow arrows by a circulation pump 19, which is driven
by a drive motor 20, in order to ensure uniform,
powerful circulation. The cooling liquid flows along
the surfaces of the laminated core 28 and through the
end windings 16 of the stator winding 15, as well as in
the axial direction in the slots in the laminated core
28, along the axial sections (cables) of the stator
winding 15. The heat dissipation from the laminated
core 28 is further improved by providing additional
openings 22 in the laminated core 28. The heat which is
extracted from the cooling liquid is dissipated by
means of a, preferably external, cooler 21. Instead of
the openings 22, radial slots 22' may also be used for
circulation of the cooling liquid in the laminated core
28.
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In addition, the iron part (the laminated core 28) of
the stator 11 is impregnated such that it is not
subject to corrosion by the cooling liquid; a
corrosion-inhibiting inhibitor may also be added to the
liquid in addition. The housing 13 is filled with
treated water, whose electrical conductivity is set
specifically. It is no longer absolutely essential for
the field in the cable insulation in the stator winding
15 to be controlled - as in the prior art cited
initially - via a grounded semiconductor layer which is
applied to the cable, and this can be provided via the
appropriately regulated electrical conductivity of the
cooling liquid (of the water). In consequence, the
field distribution in the insulation is highly
homogeneous, since the cable surface is uniformly at
ground potential. Special consideration must be given
to the water influencing the insulation characteristics
of the conductor cable, for example by means of a
silicone layer on the cable surface.
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LIST OF REFERENCE SYMBOLS
Generator
11 Stator
12 Rotor
13 Housing (closed)
14 Interior (housing)
Stator winding (cable)
16 End winding
17 Generator outgoer
18 Rotation axis
19 Circulation pump
Drive motor
21 Cooler
22, 22' Opening (in the laminated core)
23 Cooling circuit (open)
24 Filter mat
Cooling circuit (closed)
2 6 Cooler
27 Blade system
28 Laminated core (stator)
